A method of protecting a nox reducing catalyst 140 from fouling, where the nox reducing catalyst 140 is downstream of a circulating fluidized bed (cfb) boiler 120 and upstream of a particulate removal device 150. The method includes introducing a SOx removing reagent 212 in a calcium to sulfur molar ratio greater than that required for SO2 removal from a flue gas 122 generated by a cfb 120, thereby preventing SO3 formation and fouling of the nox reducing catalyst 140.
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1. A method of protecting a nox reducing catalyst from fouling, where the nox reducing catalyst is downstream of a circulating fluidized bed (cfb) boiler and upstream of a particulate removal device, the method comprising:
introducing a SOx removing reagent in a calcium to sulfur molar ratio greater than that required for SO2 removal from a flue gas generated by a cfb boiler, thereby preventing SO3 formation and fouling of the nox reducing catalyst.
13. A system for protecting a NOx reducing catalyst from fouling, where the NOx reducing catalyst is downstream of a circulating fluidized bed (cfb) boiler and upstream of a particulate removal device, the system comprising:
an injector, sprayer, or feeder to introduce into said system a SOx removing reagent in a calcium to sulfur molar ratio greater than that required for SO2 removal from a flue gas generated by a cfb boiler, thereby preventing SO3 formation and fouling of the NOx reducing catalyst.
10. A method of maintaining an amount of SOx removing reagent introduced to a flue gas processing system having a circulating fluidized bed (cfb) boiler adapted to combust one or more types of fuel , the method comprising:
combusting a first fuel in a cfb boiler, thereby producing a first flue gas;
introducing a SOx removing reagent to the flue gas processing system to remove an amount of SOx from the flue gas produced by combustion of the first fuel, the SOx removing reagent introduced in a calcium to sulfur molar ratio greater than that required for SO2 removal from the flue gas;
removing the first fuel from the cfb boiler; and
combusting a second fuel in the cfb boiler, thereby producing a second flue gas, wherein an amount of SOx present in the second flue gas is removed by the SOx removing reagent, the amount of SOx removing reagent introduced to the cfb boiler combusting the second fuel is maintained at the same amount introduced to the cfb boiler combusting the first fuel.
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This application claims the benefit of U.S. provisional application No. 61/083,576 filed Jul. 25, 2008, the contents of which are incorporated herein by reference in their entirety.
1. Field of the Invention
The disclosed subject matter relates to a flue gas processing system employing a catalyst to remove or reduce the amount of nitrogen oxides (NOx) released from the flue gas processing system. More particularly, the disclosed subject matter relates to a method of protecting the catalyst from fouling.
2. Description of Related Art
Burning of carbonaceous fuels results in generation of many byproducts, including, but not limited to carbon monoxide (CO), hydrocarbons, soot, nitrogen oxides (NOx), sulfur oxides (SOx) and the like. In the United States, release of such byproducts into the environment is tightly regulated by various federal and state laws and regulations. Accordingly, technology that reduces or eliminates the emission of CO, hydrocarbons, soot, NOx, SOx and the like, have been developed and introduced to process the exhaust gases (referred to as “flue gas”) containing these byproducts.
Flue gas treatment techniques that reduce or eliminate NOx emissions typically employ various chemical or catalytic methods. Methods include non-selective catalytic reduction (NSCR), selective catalytic reduction (SCR) and selective non-catalytic reduction (SNCR) (hereinafter collectively referred to as “NOx reducing catalysts”). Alternatively, NO may be oxidized to NO2 for removal by wet scrubbers.
The NSCR method typically uses unburned hydrocarbons and CO to reduce NOx emissions in the absence of O2. Chemical reactions on a solid catalyst surface of SCR systems convert NOx to N2. Commercial SCR systems typically use ammonia (NH3) as the reductant. SCR technology generally involves injecting ammonia into the flue gas and passing it over a catalyst where the ammonia reacts with NOx to produce molecular nitrogen and water vapor.
NOx reducing catalysts are often completely or partially deactivated when exposed to flue gas (oftentimes referred to as “fouling”). Partial or complete deactivation of the catalysts occur when calcium deposits, commonly calcium oxide, become sulfated and form calcium sulfate, thereby plugging the pores of the catalyst and interfering with the reduction of NOx. Accordingly, only certain fuels and boilers or furnaces are used in conjunction with a NOx reducing catalyst.
Partial or complete deactivation of NOx reducing catalysts may result in increased NOx emissions, partial or complete plant shut down, or replacement of the catalyst. Such drawbacks increase interruptions to plant productivity which may lead to a decrease in the efficiency of the plant as well as an increase in costs of running the plant.
Placement of a particulate removal device prior to the NOx reducing catalyst may slow down the deactivation of the NOx reducing catalyst. However, particulate removal devices increase construction and operating expenses of the flue gas processing system. Moreover, retrofitting a particulate removal device and/or a NOx reducing catalyst in a system to decrease NOx emissions is a costly endeavor due to system and operation re-design.
According to aspects illustrated herein, there is provided a method of protecting a NOx reducing catalyst from fouling, where the NOx reducing catalyst is downstream of a circulating fluidized bed (CFB) boiler and upstream of a particulate removal device, the method including: introducing a SOx removing reagent in a calcium to sulfur molar ratio greater than that required for SO2 removal from a flue gas generated by a CFB boiler, thereby preventing SO3 formation and fouling of the NOx reducing catalyst.
According to another aspect illustrated herein, there is provided a method of maintaining an amount of SOx removing reagent introduced to a flue gas processing system having a circulating fluidized bed (CFB) boiler adapted to combust one or more types of fuel, the method including: combusting a first fuel in a CFB boiler, thereby producing a first flue gas; introducing a SOx removing reagent to the flue gas processing system to remove an amount of SOx from the flue gas produced by combustion of the first fuel, the SOx removing reagent introduced in a calcium to sulfur molar ratio greater than that required for SO2 removal from the flue gas; removing the first fuel from the CFB boiler; and combusting a second fuel in the CFB boiler, thereby producing a second flue gas, wherein an amount of SOx present in the second flue gas is removed by the SOx removing reagent, the amount of SOx removing reagent introduced to the CFB boiler combusting the second fuel is maintained at the same amount introduced to the CFB boiler combusting the first fuel.
According to another aspect illustrated herein, there is provided a system for protecting a NOx reducing catalyst from fouling, where the NOx reducing catalyst is downstream of a circulating fluidized bed (CFB) boiler and upstream of a particulate removal device, the system including: a SOx removing reagent in a calcium to sulfur molar ratio greater than that required for SO2 removal from a flue gas generated by a CFB boiler, thereby preventing SO3 formation and fouling of the NOx reducing catalyst.
The above described and other features are exemplified by the following figures and detailed description.
Referring now to the figures, which are exemplary embodiments, and wherein the like elements are numbered alike:
Upon combustion of a fuel (not shown in
Still referring to
The presence of various contaminants, such as SO3, in flue gas 122 may partially or completely deactivate NOx reducing catalyst 140. In one embodiment, as illustrated in
The SOx removing reagent 212 introduced to the system may be any substance that reduces the amount of sulfur trioxide (SO3) emitted from the CFB boiler 120 in the flue gas 122. SOx removing reagents 212 include, but are not limited to, magnesium oxide and calcium-based SOx removing reagents. Calcium-based SOx removing reagents 212 include, but are not limited to, lime, limestone, calcium carbonate, calcium oxide, and the like. The SOx removing reagent 212 may be in any form, i.e., a solid, a liquid, in solution, and the like.
In one embodiment, as shown in
In another embodiment, as shown in
In a flue gas process system 400, illustrated in
Referring collectively to
In one example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio between about 2.2 and 2.8. Specific ratios include, but are not limited to 2.25, 2.37, 2.43, 2.64, 2.72 and 2.73. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.2. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.3. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.4. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.5. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.6. In another example, the SOx removing reagent 212 is introduced at a Ca/S molar ratio of about 2.7.
In another example, the SOx removing reagent 212 is introduced to the system where the molar ratio of the SOx removing reagent 212 is introduced at a level between 2 to 3 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas.
In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.2 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.2 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.3 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.3 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.4 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.4 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.5 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.5 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.6 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.6 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas. In yet another example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.7 times the molar ratio needed to remove at least 90% of the SO2 from the flue gas. In still a further example, the SOx removing reagent 212 is introduced in an amount where the molar ratio amount of calcium introduced to the flue gas processing system is at a level of about 2.7 times the molar ratio needed to remove at least 95% of the SO2 from the flue gas.
The amount of the SOx removing reagent 212 introduced to the flue gas processing system is effective in protecting the NOx reducing catalyst 140 from partial or complete deactivation since it reacts with the SOx present in the flue gas 122, thereby reducing the amount of SO3 present in the NOx removing catalyst 140. As will be appreciated, the actual amount of SOx removing reagent 212 effective to protect the NOx reducing catalyst 140 from partial or complete deactivation will vary from system to system.
As shown in
Control of an amount of the SOx removing reagent 212 introduced to the system 500 may be accomplished by providing a control system 240. The control system 240 includes a SOx sensor 242 responsive to the amount or level of SOx present in the flue gas 122. In one embodiment, the SOx sensor 242 senses an amount or level of SO3 present in flue gas 122. The SOx sensor 242 is in communication with a controller 244. The controller 244 is configured to generate and output a control signal 244a in response to the input from SOx sensor 242. The controller 244 is in communication with a flow/valve control device 246, which, as shown in
In one example, if an amount of SOx, such as SO3, exceeds a predetermined level set by a user, control system 240 increases the amount of the SOx reducing reagent 212 introduced to the system 500. In another example, if an amount of SOx, such as SO3, is below a predetermined level set by a user, control system 240 may either maintain or decrease an amount of the SOx reducing reagent 212 introduced to the system 500.
It is contemplated that the flue gas processing systems illustrated in
In one embodiment of maintaining an amount of SOx removing reagent 212 introduced to a CFB boiler 120, the CFB boiler 120 is adapted to combust one or more types of fuel. A first fuel, such as, but not limited to PRB, is combusted in the CFB boiler 120 to produce a first flue gas. The SOx removing reagent 212, such as limestone, is introduced to the system to remove an amount of SOx from the flue gas produced by combustion of the first fuel. As shown in
As discussed above, the SOx removing reagent 212 may be introduced in one or more locations throughout the system, including, but not limited to, directly into the CFB boiler 120, a position between the CFB boiler 120 and the NOx reducing catalyst 140, the fuel 220, or a combination thereof. The SOx removing reagent 212 is introduced in a calcium to sulfur molar ratio greater than that required for SO2 removal from the flue gas.
The first fuel is removed from the CFB boiler 120 and a second fuel, such as, but not limited to, bituminous coal, is added to the CFB boiler 120 and combusted. Combustion of the second fuel creates a second flue gas that includes, inter alia, SOx. The SOx present in the second flue gas is removed by the SOx removing reagent 212, the amount of which is maintained at the same amount (or level or ratio) that was used when the first fuel was combusted.
Unless otherwise specified, all ranges disclosed herein are inclusive and combinable at the end points and all intermediate points therein. The terms “first,” “second,” and the like, herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. The terms “a” and “an” herein do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced item. All numerals modified by “about” are inclusive of the precise numeric value unless otherwise specified.
While the invention has been described with reference to various exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
Larsson, Mikael, Czarnecki, Lawrence J.
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